HU230921B1 - A method for the economical production of a reduced deuterium containing water used in medicine - Google Patents

Description

PROCEDURE FOR THE ECONOMIC PRODUCTION OF REDUCED DEUTERIUM WATER, MAINLY USED IN MEDICINE

The present invention relates to a process for the economical production of Deuterium Depleted Water (DDW), in particular for medical use, in particular for the prevention, alleviation and therapeutic treatment of cancer, in which mineral hydrocarbons are oxidized, preferably burning natural gas and burning natural gas. water is condensed.

It is well known and proven in the field of medicine that the use of water with reduced deuterium content can achieve significant results, especially in the early stages of cancer, in reducing them, slowing down aging, but also in many other fields of medicine. In addition, water with a reduced deuterium content is very much. a pharmaceutical composition may contain an ingredient that complements the therapeutic effect of the essential active ingredient. In many cases, only the high price of DDW is the reason why it does not have more applications. Demand for this water is therefore expected to increase in the near future.

There have been a number of successful solutions in the art for the production of this product. Distillation and rectification methods are the most common methods for achieving reduced deuterium content. The difficulty is due to the low separation factor in the H? O, HDO, D-> O systems, the difference of barely 1 ° C (at bar pressure). Such columns operate with a large number of plates, making column systems expensive.

This difficulty can be found in RU2295493 and HU 208084. According to the process described in CN 101481088, a. DDW is produced by fractional distillation of the starting water on a plastic composite column. Large plate count

This is also a complicated procedure requiring SZTNHM00132866. Similarly, according to CN 101 597 031, deuterium-poor water is produced by multi-stage rectification using several columns, in which the isotopes of hydrogen in the "bottom product" and the "head product" are enriched. Due to the high energy demand, the process is very expensive.

Another common method is electrochemical, water-decomposing hydrogen generation and its combustion. The difference in the deposition stress of prosium and deuterium is the basis for the enrichment of prosium. This is what the. RU 101648 1.

Water with a deuterium content of .1.1.1 to 135 ppm is produced by electrolysis and / or distillation for use in the food industry (brewing, preparation of aromatized juices) according to HU 209 787. All three production versions are unfavorable: due to the cost of the distillation system and the energy consumption of electrolysis.

The method according to the Hungarian description published in HU 0800528 is a two-step solution, in which hydrogen generated by electrolytic combustion is first burned, and the water with reduced deuterium content thus obtained is subsequently rectified. The process not only has the disadvantages of the previous ones, but on the one hand the process itself is very complicated, and on the other hand the combustion of hydrogen also raises serious occupational safety problems.

Among the previously known solutions, in the process according to HU 21.74.18, rock salt is decomposed by electrolysis on a mercury blanket. The resulting metal forms amalgam from sodium. Sodium mercury amalgam is converted to NaOH on contact with water and hydrogen is evolved from it. Hydrogen is purified, incinerated, and condensed to produce water with reduced deuterium content. The latter is then rectified to further reduce the deuterium content. The operation is effective because. It results in a D / H ratio of 50-60 ppm, but has the disadvantage of many steps, the dangers of treating hydrogen, and the proportion of extraction, in other words, the significant cost of the latter.

The object of the invention is to produce water with reduced deuterium content in a more economical manner than hitherto, starting from water obtained as a combustion product of fossil hydrocarbons, which is easily accessible and available in sufficient quantities. It is an important requirement and task within this to find a starting material from which a significant amount is actually available, namely with a low production cost, so as not to significantly increase the number of products to be manufactured, e.g. prices of medicines.

Just as the price of this 'intermediate' product can be reduced, so can its use. This is because the raw material is useful not only on its own, but as a solvent or reaction medium for other pharmaceutical compositions, and as an ingredient in food products, cosmetics, and many other fields.

The inventor was initiated by Robert C. Burruss and Christopher D, Laughrey, "Covariation of carbon and hydrogen isotopic compositions in natural gas: separating biogenic, thermogenic and abiotic (inorganic COa reduction) sources," which is part of the United States Geological Survey. published as a publication. The publication is a comprehensive study of the study of mineral hydrocarbons.

That is also part of the study. the isotopic composition distribution of the natural gases formed in different ways according to their mode and location of formation. However, the isotopic composition has no effect on the utilization and expedient combustion of natural gas. Nor did the authors examine anything about the deuterium - hydrogen isotope ratio in the resulting water in the case of methane combustion.

The idea of the invention was based on the recognition that it should be examined whether what we will experience if we take samples from different combustion products of burned natural gases. After sampling, the combustion products. measured, compared, and ..... by no means obvious - we came to the surprising result that the ³ H isotope, in other words deuterium, is present in a smaller proportion among the hydrogen atoms bound in fossil hydrocarbons.

With this recognition, the task can be solved by capturing and purifying the water produced as a combustion product of fossil fuels, as well as by known distillation processes. The condensed water formed as a combustion product is also clean, sterile and has a negligible salt content. Part of the recognition is that such condensed water can be obtained easily, cheaply and in large quantities in a number of cases, preferably by burning the hydrocarbon in a condensing boiler known per se when other waters are available to a limited extent or only more expensive.

Accordingly, it is an object of the present invention to provide a process for the economical production of deuterium-reduced water, especially in medicine, by oxidizing hydrocarbons of mineral origin, preferably by burning natural gas, and condensing the water formed from the combustion product. The essence of the process is based on the combustion of the hydrocarbon, preferably in a condensing boiler, to capture the condensed water formed during the condensation to produce water with a natural deuterium content of less than 155 ppm, an average of 122-1.26 ppm deuterium, and then the captured water is optionally subjected to further fractionation distillation suitable for deuterium depletion.

A further advantageous feature of the process according to the invention is that, before human consumption, the water with reduced deuterium content is passed through a basic bed with an average grain size of 5 mm, preferably dolomite or limestone crushed stone.

In particular, sodium bicarbonate (NaHCCh) can be added to the water in an amount of 1 g / l to make it suitable for human consumption.

The main advantage of the process according to the invention is that it is based on a feedstock, fossil hydrocarbons, in particular natural gas, in which deuterium is already present in a lower proportion than usual. Salt, today in the developed world, combustible natural gas is available almost everywhere virtually indefinitely. It is also advantageous that further reduction of the lower deuterium content requires much fewer distillation steps. The process is thus simpler and, due to all the factors mentioned so far, substantially more economical than any of the known processes.

The process according to the invention is illustrated by the following examples without limiting the scope of the invention to these examples only.

Example 1

On a domestic gas stove, several liters of cold water were heated in a stainless steel pot over a gas flame. Condensate on the outside of the slightly sloping vessel is drained and a sample of this water was taken. The sample was weighed and as a result of mass spectrometric measurement, its deuterium content showed 125 ppm.

Example 2

In a gas boiler used in households, we burned natural gas with air (Cfh + 20 * 2 ”CO2 + 2H2O). The calorific value of natural gas was 35 MJ / m ³ . Water was separated from the discharged combustion product by means of a cooling system. That one. we found that the deuterium content of the separated water was 122 ppm.

Example 3

In everything according to Example 2, we proceeded. In particular, in order to make it suitable for human consumption, 1 g / l of sodium bicarbonate (NaHCO3) was added to the water and filtered off.

Example 4

Again, the procedure was as in Example 2, and preferably the water was passed through a lime bed with an average grain size of 5 mm and filtered to make it suitable for human consumption. The water thus became enriched in useful ions and the deuterium content remained low.

Example 5

The procedure of Example 2 was continued. The sample was re-examined at the Institute of Geochemistry of the Hungarian Academy of Sciences in order to confirm the results obtained so far. During the additional investigations, we burned natural gas from several locations in Hungary. The deuterium content of the water obtained as a combustion product was between 122 and 126 ppm.

The significance of the process underlying the invention is that it proposes as a starting material a new starting material which is available almost everywhere, and that the process itself is simple and involves fewer steps than previously known processes. Therefore, it is more technically and economically advantageous than them.

Claims (2)

SZA BADA LMIIGÉ NYPOTPO .1. Process for the economical production of deuterium-reduced water, especially in medicine, by oxidizing hydrocarbons of mineral origin, burning the preferred natural gas and condensing the water from the combustion product, characterized in that the combustion of the hydrocarbon is preferably carried out in a condensing boiler. precipitated water is captured to produce water having a natural deuterium content of less than 155 ppm, with an average deuterium content of 122-126 ppm, and the captured water is optionally subjected to further fractionation by deuterium depletion. Process according to Claim 1, characterized in that, before human consumption, the water containing reduced deuterium is passed through a basic bed with an average grain size of 5 mm, preferably dolomite or limestone crushed stone.